KR101951947B1 - Medical procedure training system - Google Patents

Abstract

A medical training development system for the development of a medical training scenario (15) is disclosed. The medical training development system includes a database 110 having a plurality of pre-programmed event modules 120, a scenario linked to the event module database 110 for accessing the event module 120 and programming the medical training scenario 15, A programming system 140, and a medical training scenario database 10.

Description

{MEDICAL PROCEDURE TRAINING SYSTEM}

[Cross reference to related application]

This application is a continuation-in-part of U.S. patent application filed on April 19, 2012 by the same inventor as U.S. Patent Application No. 13 / 451,052 entitled "Method and Apparatus for Developing Medical Training Scenarios" U.S. Patent Application No. 13 / 451,052, filed April 19, and U.S. Patent Application No. 13 / 466,688, filed May 8, 2012, the entire contents of which are incorporated herein by reference.

[TECHNICAL FIELD]

The technical field of the present invention relates to a method and apparatus for developing a medical training scenario and a computer program product stored in a non-volatile memory and enabling a general purpose computer to perform the method when executed on a general purpose computer.

Medical training systems are known in the prior art. An example of a medical training system is a medical simulation system such as that produced by Laerdal Medical AS based in Stavanger, Norway. These medical simulation systems enable the student's training in responding to the patient's medical needs by simulating medical emergencies or other medical procedures. Such medical needs include, but are not limited to, casualty assessment, emergency response, delivery and cardiopulmonary resuscitation (CPR). Cardiopulmonary resuscitation is an emergency procedure performed in an effort to manually preserve uninjured brain function until additional measures are taken to the patient to restore normal blood circulation and respiration.

Medical simulation systems often use mannequins. A mannequin is a full-size anatomical human model used, for example, as a teaching aid in medical education to train students, physicians, nurses, emergency medical centers, and other learners in human resuscitation and emergency care . Many companies produce mannequins. For example, Laerdal has produced mannequins in various forms since the 1960s. In general, a mannequin is a three-dimensional model of all or part of a human being and is intended to be as realistic as possible in order to provide the learner with an actual situation. Mannequins can be used to train learners using so-called "training scenarios." The training scenarios are designed to be realistic simulations of medical emergencies in real life situations. The instructor can conduct one or more training scenarios and review how the learners respond to the implemented training scenarios.

Medical simulation systems used today are concentrated in the use of resources. For example, a medical simulation system requires different and individual content to suit the educational needs of the student. Such educational content needs to be evaluated as clinically accurate and needs to be adjusted for use in different medical simulation systems or in different situations. The evaluation of the student's performance by the instructor (or examiner) is often subjective and / or handled by evaluation tools that are not well integrated into the medical simulation execution tool. Most tracking and training records are traditionally manually handled or manually entered into a learning management system. This is a burden on the administrator and also creates potential errors.

More recently, e-learning systems have been introduced. For example, Laerdal has developed a self-directed computer-based process to acquire basic life support certificates and is marketed under the trademark HeartCode ™. The HeartCode system includes a local database that allows the student to obtain a certificate and records the name of the student who obtained the certificate.

A number of e-learning systems for medical simulations are known. For example, Laerdal Medical, along with a US company, HealthStream in Nashville, Tennessee, suggests SimStore, an e-warehouse that supports the distribution and sale of medical simulation content. Further details of the SimStore and related SimCenter products are contained in Laerdal Product Information Bulletin 11-002, dated April 18, This Product Bulletin describes the worldwide launch of SimCenter products. Medical simulated content in SimStore is designed for use with training products such as those produced by Laerdal, Inc. and other medical simulation products.

A number of patent applications are known for incorporating various e-learning systems. For example, U.S. Patent No. 6,193,519 (Eggert et al., Assigned to Gaumard Scientific) provides an interactive program for use with a simulator, such as a mannequin, and a virtual device for performing simulated patient management activities under the direction of the program And a computerized training system. The interactive program displays the selection of the module to assist the user in learning the patient management protocol. The module is user selectable to provide different interactive training sessions that include different patient management protocols. A virtual device used in conjunction with a simulator in performing a patient management activity collaborates with a sensor in a mannequin, but interfaces with a computer program, thus providing feedback to the program about the activity of the student and using the virtual machine in the simulator Confirm proper placement.

Similarly, U.S. Patent Application Publication No. 2005/0186549 (Huang) teaches a method and technology assessment tool for managing a test session at a medical technology testing center that includes a plurality of evaluation stations. The disclosed method comprises constructing a plurality of evaluation stations associating each evaluation station with a case type before the start of a test session, receiving an electronic identity of a student at one of the evaluation stations, And automatically assigning the student to one of the evaluation stations.

U.S. Patent Application Publication No. 2011/0223573 (Miller et al., Assigned to Kb Port) teaches methods and apparatus for integrating multiple medical simulators. The apparatus includes a plurality of medical simulators simultaneously receiving at least one electronic data source input from each medical simulator and places such electronic data source inputs in a common digital memory buffer in a time stamped manner for at least a given training event. Each of the electronic data source inputs forms a data record over the entire simulated parameters of the training simulator or the events of the physical parameters of the training simulator. The common memory buffer allows independent, simultaneous, synchronized, user-controlled playback of individual inputs received in the memory buffer in any number of user-defined configurations.

The paper "Healthcare simulation and its potential areas and future trends" (SES M's magazine 2011 / No.1 (January), pages 1-6, J. Barris) describes not only the most relevant topics for future research, We discuss the pressures on reporting on management simulations and controlling costs in healthcare services. The paper notes that health care simulations have broad application potential for clinical simulation, surgical simulation, management simulation and training simulation. One of these problems associated with healthcare simulation is the increasing complexity of the healthcare process. This complexity is also reflected in the increasing complexity of simulation tools. For example, it is essential to generate data from many different health care simulations and compare this data. Data needs to be compared across students, institutions (such as hospitals or universities) and private hospitals. Thus, the data needs to be based on a common format that allows such comparisons to be made.

The increasing complexity of healthcare protocols means that the simulation becomes more complex. However, there are common elements in simulations that can be reused and reprogrammed in different simulations. In addition, these common elements can be compared against the performance of the same student for different students and for different situations.

The term " student " as used in this disclosure is not intended exclusively to mean a graduate student or college student participating in the MD course, B. Med course or the like. Also, the term "student" is intended to apply to health care professionals, such as nurses, doctors or emergency medical services, who already have the qualifications and basic education required to maintain their proficiency. Accordingly, it will be appreciated that the term "student " is broadly understood to mean a person who is trained in the context of the present disclosure using a medical simulator device, e-learning or practical experience.

In addition to traditional medical simulation systems, new types of medical and medical monitoring systems have been introduced to monitor and evaluate students in real-life situations. See, for example, U.S. patent application publication no. 2008/0312565 (assigned by the Board of Trustees of the University of Texas system in Austin, Texas, and assigned to Laerdal Medical, Stavanger, Norway) is a thin, substantially flat flexible substrate with one or more sensor arrays, a power supply, an output interface, A card-shaped CPR sensor having a processor or analog circuit included in the card substrate will be described. The CPR sensor of US 565 publication can easily be in a wallet or other personal belongings or garments so that the CPR sensor can be quickly located during an emergency. The CPR sensor may be placed in or near the hands of the person administering the CPR and may provide immediate feedback to the person administering the CPR to indicate that he or she is managing the CPR correctly. Integration of the output interface enables the transfer of actual data to the database for further evaluation at a later stage. In the event of an investigation or litigation involving the performance of a CPR, the storage of actual data in the database may be very useful in reviewing the individual's ability to perform CPR and / or evaluate CPR performance.

Accordingly, there is a need to develop medical simulation systems that integrate medical simulation execution tools with assessment tools and learning management systems and allow comparison of data across multiple medical simulation scenarios.

The present disclosure includes a training device, a medical simulation management module coupled to the training device, and at least one medical training module executable in the training device. The medical training module includes at least one medical training scenario for the training of a student comprising at least one scenario code and at least one assessment / annotation template. The partitioning of the medical training modules into scenario code and evaluation / annotation templates allows for greater degree of flexibility. Similar or identical evaluation / annotation templates may be used for different or modified medical training modules, and more than one evaluation / annotation template may be associated with the same scenario code or medical training module. This allows different training items to be emphasized differently.

In an aspect, the medical training system further includes a medical scenario development system having at least one of a pre-programmed event module or a preprogrammed medical training scenario with an associated evaluation / annotation template. These preprogrammed event modules or preprogrammed medical training scenarios and evaluation / annotation templates represent standardized medical procedures for the formation of scenarios and enable reuse of medical scenario codes and evaluation / annotation templates in different medical scenarios, This not only allows comparison of trained medical procedures, but also improves the quality of the code (and the training accordingly).

The medical training system also includes a teacher control device connectable to the medical simulation management module. The instructor control device can control the execution of the medical training module. The instructor control device can use the evaluation / annotation template to input student data. This enables standardized data items to be used and later stored in the student record database.

A method for training and evaluation of a student is also disclosed. The method includes selecting a medical training module, executing a medical training module, generating performance evaluation parameters for performance stages of the medical training module, and scoring performance evaluation parameters. The evaluation parameters are stored in the storage device.

The step of generating the evaluation parameter includes accessing the evaluation / annotation template and generating a scoring module for scoring the student performance on the medical procedure. The generation of the evaluation parameter from the evaluation / annotation template allows a plurality of evaluation parameters to be generated based on the description to be scored.

Also disclosed is a computer program stored in a non-volatile storage having logic means for executing a medical training module and generating evaluation parameters for the performance steps of the medical training module.

Figure 1 shows an overview of a medical training system.
Figure 2 shows a flow chart of a student training method in a medical situation.
Figure 3 shows a flow chart of a method for collating student performance data from an actual medical procedure.

The present invention will be described based on the drawings. It is to be understood that the embodiments and aspects of the invention described herein are merely examples and that the scope of protection of the claims is not limited in any way. The invention is defined by the claims and their equivalents. It is to be understood that features of one aspect or embodiment of the invention may be combined with features of other aspects and / or embodiments of the invention.

A medical training development system (5) is shown in the structural view of FIG. The medical training system 5 has a central management module 10 running on a general purpose computer such as a server. It will be appreciated that the central management module 10 may be run as a local server or a remote server, or it may be part of a module running on a cloud server. The central management module 10 comprises one or more medical training modules 15 that can be stored in the same general purpose computer or in a separate data store.

Medical training module 15 includes, but is not limited to, training scenarios using simulations of medical procedures such as cardio pulmonary resuscitation (CPR) or other highly sophisticated life support cases. It will be appreciated that many such medical training modules 15 are possible and that variations of the medical training module 15 are possible. For example, one of the medical training modules 15 may include medical training scenarios associated with adults, but similar medical procedures performed on infants may be different or coordinated due to the modified medical training scenarios, need. The data input device 25 is used by an instructor to input data and / or to control medical training scenarios.

The medical training module 15 is programmed to execute a central management module 10 that is accessed by a patient simulator such as a mannequin 20, a personal computer 30 or a remote workstation. The personal computer 30 may be a stand-alone personal computer, a dumb terminal, a tablet computer, or a smart phone.

It is known that different medical training modules 15 running on the central management module 10 have some degree of commonality in which similar medical techniques are trained. At least some of these common aspects are independent of the type of medical procedure being trained by one of the medical training modules 15. This similar medical technique represents an example of an "event ". The term "event " is used in this context to describe various components or stages of a medical procedure or training scenario. A common event may have a common data element associated with it. The common data element is, for example, a parameter indicative of the performance of the student in performing one or more medical skills across different ones of the medical training modules 15. There may also be a "special" event that is specific to the medical training scenario being performed and has nothing to do with any other of the medical training scenarios.

Medical simulations typically involve multiple events. The sequence of events and events will change during the course of the medical training scenario represented by the medical training module 15. For example, a first set of events A would occupy the first 10 minutes of the medical training scenario performed by the student. After running the medical training module 15 for 10 minutes, the medical condition of the patient can be considered to change dramatically. This change in medical condition can be done automatically (i.e., preprogrammed with medical training scenarios), or by instructor monitoring student performance and manually initiating the change. The medical training scenario would then change from a first series of events to a second series of events. The manner in which the instructor uses the data entry device 25 or introduces a new event to change the execution order of the event set is described below.

An event category is a grouping of events. Each of the events will be assigned a default category, but the category can generally be changed, or a new category can be defined. The type of category associated with the event is assigned to the event and is stored with the event in the metadata. Similarly, a composite event is a small group of individual events that are locally located or grouped against each other. For example, the so-called " six rights of medication "includes six different events. Each of the six different events is individually programmed (and can be called independently). Thus, although different events representing each of the six accuracies are available separately, they are also usable as composite events.

In addition, the mannequin device 20 is connected to the central management module 10. The connection between the mannequin 20 and the central management module 10 may be cable and / or wireless, but this is not a limitation of the invention.

A personal computer or other type of display terminal 30 is connected to the central management module 10 in a cable and / or wireless manner. The student and / or instructor may operate the personal computer 30. [ The personal computer 30 enables access to the medical training module 15 that is executed in the central management module 10 and allows the student or instructor to access patient records Access to the patient records in the database 60 may be enabled. However, the laws governing access to such private data are extremely restrictive, and therefore the medical training module 15 may record data in these patient history databases 60, but rarely allows access to actual patient records It will be understood. The patient record database 60 may be protected by a firewall 70. It may be possible to allow access to anonymous or dummy patient records. In many training systems, there may be no patient record 60 or only a dummy patient record.

The personal computer 30 operated by the instructor will allow the instructor to enter data relating to the performance of the student and will also include a debrief manager. The purpose of the debrief manager is to enable the instructor to discuss the student's performance during the medical simulation. The debrief manager includes a program module running on the personal computer 30 and can access data entered by the instructor during student monitoring as well as video made for the student. Instructors may enter numerical grades and / or annotations on student performance.

The data manager 40 is connected to the central management module 10 by cable or wirelessly. The function of the data manager 40 is to extract from the central management module 10 any data related to the student's performance in performing the medical training scenario. The data is extracted in the form of long files, in one aspect of the system. In addition, the associated data may be extracted into other structured data formats. The data manager 40 may receive and deliver data from data entered by the instructor in the mannequin 20 and / or the personal computer 30 and / or the data input device 25. [ The data manager 40 may receive data (as described above) from the patient record database 60, communicate data therefrom, and / or may receive or record data to the student record database 50. The data manager 40 is shown as an individual unit in this figure, but may be included in the central management module 10, or may be elsewhere.

The data manager 40 may be part of a learning management system that allows a student to monitor his or her learning goals and performance.

The data in the student record database 50 may include, for example, the name of the student as entered via the personal computer 30, any data relating to the type of medical proficiency the student is trained for, Including the expiration date of the certificate requirement. The student record database 50 may also include a verifiable key (e. G., ≪ / RTI > which can be accessed by an employer or a management authority to verify any information, key.

FIG. 2 illustrates an example of a medical training scenario development system 100. FIG. The medical training scenario development system 100 includes a medical training module 15 as described above to be run on the central management module 10, one or more mannequin devices 20 and / or one or more personal computers 30 Creating and / or modifying data.

The medical training scenario development system 100 includes a repository 110 and a scenario programming system 140. The scenario programming system 140 is programmed by the scenario programmer 130. The storage 110 includes a plurality of event modules 120 and may also include a preprogrammed medical training module 15 '. It will be appreciated that although the medical training scenario system 100 is shown as a separate unit in this figure, the medical training scenario development system 100 may be part of the central management module 10 or may be executed in the personal computer 30. [

The event module 120 is a series of events that can be used to operate the mannequin device 20, the central management module 10 and / or the personal computer 30 to develop the performance evaluation template 123, as well as to implement the event (Coding) of < / RTI > The event module 120 includes instructions for extracting any required data from the student record database 50 and from the personal computer 30 or the mannequinevice 20 and instructions for retrieving the data from the student record database 50 (or other database) For example. The event module 120 is preprogrammed and can be used to develop various medical training scenarios.

In addition, the medical training scenario development system 100 may include one or more existing (i.e., pre-programmed) medical training modules 15 'and may be adapted to change, update, , And can be used for re-coding. In other words, a "mother" medical training module 15 'may be used to generate a "daughter" medical training module 15 ".

In one aspect, event module 120 (and medical training module 15, 15 ', 15'') is programmed using an XML schema. The XML schema is stored in non-volatile memory forming the storage 110. A non-volatile memory includes a plurality of memory elements for physical storage of data. The XML schema includes commands for operation of the central management system, the mannequin device 120 and the personal computer 30 as well as the metadata.

Metadata is "data about the data" and is essentially a descriptor describing, for example, the role of the student and / or lecturer, the intended performance of the medical training scenario, and the parameters collected about the performance of the student . The metadata may be interpreted by the mannequin 20, the data input device 25, the personal computer 30, the data manager 40, etc., and may partially identify the event programmed by the event module 120, Can be used to prepare for the collection of data related to performance by the student of the event. The use of metadata enables cross-referencing of data collected over one or more events.

Examples of metadata include:

ViewItems Key - the unique ID of the event

DisplayName Lang - the language of the event for translation

ViewItem - Event

Event - normal event, no additional value

StringEvent - event with a text-based value

EnumEvent - event with multiple text-based values

IntEvent - an event with an integer value

DoubleEvent - event with a numeric value

DrugEvent - events with values for dose and dose route

CompositeViewItem - an event with a sub-event inside

BoolEvent - Event with true / false values

EnumEvent DefaultValue - default value for events of type enumevent

AllowMultiple - Determines whether multiple values can be registered for an event

Id - The name of the event.

Lang - the language of the event

Roles - If the event has one role or many roles associated with it, for example, it means that the junior is expected to perform this event

Role Lang - the name of the role

InstructorProperties - Properties that deal with forming more intelligent workflows during simulation

Critical - Displays an icon on the event that can cause extreme results in medical training scenarios. An important event that is not performed by the student to the patient will be the failure of the medical training scenario being performed.

ShowCounter - Whether the event should indicate a counter each time it is registered

Count - The actual number of times the event has been registered (requires that ShowCounter is enabled)

Highlight - The next event expected by the scoring algorithm should be emphasized to make it easier for instructors to find.

ShowOnceInView - If set to true, the event will disappear from the view on the instructor's device when the event is registered. This is useful for events that occur only once.

HideWhenTimeInView_Seconds - Perhaps the event is only relevant for the first 5 minutes, after which the event probably will not happen at all. This is the ability to automatically hide events after a given time.

EventInfo - This is information about the event, for example, what the event is actually.

LogMessage Lang - This is the information that goes to the log along with the registration of the event.

UnsetEvent ShowMainEvent - Some events have an associated "opposite event" such as an intubate or an extubate

Id - The name of the opposite event.

Lang - a language for translation

AntiRoles - Role for opposing events

EnumValue - the actual value of the event set by the registration

The scenario programmer 130 uses the preprogrammed medical training scenario and / or the event module 120 stored in the repository 110 to develop his medical training module 15 '. Thus, for example, the scenario programmer 130 may always use the event module 120 associated with "hand washing" in a variety of different medical training scenarios. The metadata associated with the event module 120 "handwashing" may be used to determine whether individual students wash their hands at work and whether they wash their hands at work when the same student performs other things in a medical training scenario Allows comparison across healthcare training scenarios. This information may be stored in a common data element as part of the student record database 50. [ The event module 120 with standardized reports embedded with XML code can be used to transfer data to the student record database 50, as described above.

In addition, the use of the event module 120 ensures consistency of coding. There will be little variation between events that must be the same. Thus, the event module 120 is able to provide greater consistency of training and increased productivity of development of the medical training module 15 by the scenario programmer 130 without the need to consistently reprogram the task, Enabling a greater degree of comparison between the medical training module 15 and the performance of the student.

It will be appreciated that the event module database 110 may include event modules 120 as well as preprogrammed composite events (such as the six degrees of accuracy of the medical procedures described above). It will also be appreciated that the scenario programmer 130 may further program his or her additional code 150 in the scenario programming system 140 if the preprogrammed event module 120 is not available. If additional code 150 is then stored in storage 110 or elsewhere, such additional code 150 may be stored and reused by other scenario programmers.

The output of the scenario programming system 140 is an updated medical training module 15 " that is provided throughout the medical training module 15 or the central management module 10.

The patient record database 60 is one of the most sensitive databases and is generally generally protected by an additional isolator 70, such as a firewall, to prevent unauthorized access. The patient record database 60 is generally accessed only when a medical procedure is performed on an actual patient, as opposed to performing a medical training scenario on the mannequin 20 (or the personal computer 30) The data related to the performance is incorporated into the central management module 10.

The quality control system 90 is connected to the central management module 10 to monitor the quality of the training. The quality control 90 will generally have access to anonymous data from the central management module 10. That is, there is no access to the student's name or other identity and / or patient's name and / or other identity. In addition, the quality control system 90 can be used to data mining the student record database 50 to compare the quality of the training throughout the student. The use of metadata in the event module allows the student record database 50 to be populated with standardized data, allowing such comparisons to be made.

It will be appreciated that the illustrated mannequin 20 need not be located in a central training unit. In contrast, the mannequin 20 can be accommodated in a vault near the hospital's ward to ensure that the student is trained on a regular basis. This will allow the student to undertake regular medical training whenever he or she is comfortable with it. There is no need for a student to enroll in a training course to obtain a certificate renewal.

It is also advantageous to have the mannequin 20 near the student's place of work so that the student can be instructed to undertake a periodic re-training process in order to maintain his or her proficiency in performing the medical procedure, e. It is possible. The reeducation process is an example of the medical training module 15, and other reeducation processes may be provided at different intervals.

In addition, the personal computer 30 will allow the student to undertake periodic and continuous training for various aspects of the medical procedure. For example, the guidelines of the American Heart Association for CPR have recently been updated. The central management module 10 notifies the student of the update and processes the appropriate medical training module 50 to be updated by the student to be updated for the revised medical procedure. The central management module 10 records the student's completion of the training and provides feedback to the student and / or quality control 90 so that important actions can be taken.

The use of the event module 120 facilitates the modification of the training to be performed and thus ensures that the individual student can be assured that the student is performing well even when, for example, It will be appreciated that the medical training scenarios may vary slightly between different re-tutor courses. The metadata in the event module 120 allows for easy comparison between the performance of the student in the current medical training scenario and the past performance of the student.

The mannequin 20 and / or the personal computer 30 records the performance of the student when performing the medical training module 15 and provides feedback to the central management module 10. In particular, this feedback may include whether the student needs further training and / or meets the requirements to obtain a certificate. In one other aspect of the invention, the instructor or verifier has a data entry device 25 that he uses to record the performance of the student and to communicate the details of the performance to the central management module for review and recording. The data input device 25 may include a debrief viewer.

The data input device 25 receives the instructions and information encoded in the medical training module 15. If different data entry devices 25 can perform similar functions, the use of XML data means that this function can be performed by this data entry device 25. [ The data input device 25 includes a code for interpreting the XML data. The data input device 25 also receives instructions that allow the instructor to change the order of the medical training scenarios. The data may be input at the data input device 25 using free-text initiation or by standardized input values generated by the initiation / evaluation template.

It will be appreciated that the functions of the central management module 10, the quality control 30 and the data manager 40 overlap to some extent. These are generally implemented as a computer program running on a general purpose computer, and the instructions are stored in a non-volatile memory device. It will be further understood that the components may be implemented in different ways depending on the general purpose computer being executed.

In another aspect of the present invention, the data input device 25 may be a code sheet written by a nurse or lecturer and written to an appropriate log. This code sheet will contain performance evaluation parameters. Any data from the log or code sheet, such as performance evaluation parameters, may be transmitted to the central management module 10 electronically or by manual input.

Another example of a data input device 25 used in the present disclosure is an enhanced video system developed by Laerdal and described in a press release dated March 30, The enhanced video system includes an XML file that is supplied to the medical training module 15 and that originates from a preprogrammed event module to understand which items should be recorded and how the items should be stored in the student record database 30 Will interpret.

FIG. 3 shows an example of a workflow used for training and evaluation of a student, including selection of the medical training module 15 at step 300. At step 310, the medical training module 15 is executed in the mannequin 20 or personal computer using the medical scenario code.

In step 320, a performance evaluation parameter 17 is generated using the performance / annotation template 123. The performance evaluation parameter 17 is generated in the personal computer 30 or the data input device 25. [ As described above, the performance evaluation template 17 is associated with the performance steps of the medical training module 15. In step 330, the instructor may mark performance evaluation parameters 17 using a standardized rating scheme. At step 340, the performance evaluation parameters 17 are stored in a storage device, such as a student-written database 50 in a structured manner that facilitates easy access.

The generation of the evaluation parameter 17 includes accessing the evaluation / annotation template at step 320 and generating a scoring module for grading student performance on the medical procedure.

Finally, at step 350, the student may be debriefed using the de-brief viewer.

It is also possible that an automated scoring for the student is developed based on the results of the scoring module. For example, an evaluation of a student's skill in dealing with heart attacks may be a weighted average of clinical skills and team skills. Clinical and team skills are subdivided into smaller events, each of which is individually scored and graded. Then, the overall rating of the medical procedure is the weighted rating of all the smaller events. There are some "critical" events mentioned above. If these important events fail individually, the entire evaluation fails.

It will be appreciated that the systems and methods described herein can be performed using a general purpose computer specifically programmed to perform these tasks. Further, the apparatus and method described herein may be embodied as a combination of hardware and software. The software can be programmed in various computer languages. In order to simplify the collection and operation of the data, an XML format has been developed for the medical scenario 15. The individual devices on which the medical scenario is running can interpret these XML instructions in a suitable manner and ignore the XML file format that is not associated with the device. It will be appreciated that the XML file format is just one example of a suitable file format. Accordingly, the invention should not be limited by any exemplary embodiment, but should be defined only in accordance with the following claims and their equivalents.

5 Medical Training Development System
10 Central Management Module
15 Medical Training Modules
17 performance evaluation parameter
20 mannequins
25 data input device
30 Personal computers
40 Data Manager
50 Student Record Database
60 Patient History Database
70 Firewall
90 Quality control system
100 medical training development system
110 store
120 event module
130 Scenario Programmer
140 Scenario programming system
150 Additional code

Claims (9)

A medical training system (5) for testing a plurality of medical techniques,
A mannequin 20;
A medical simulation management module 10 connected to the mannequin 20;
A plurality of medical training modules (15) feasible on the mannequin (20) and comprising at least one medical training scenario for training a student in the plurality of medical technologies;
At least one event module comprising a series of instructions for implementing a plurality of events to test the plurality of medical technologies; And
At least two assessment / annotation templates for recording results from the plurality of events that test one or more of the plurality of medical techniques, wherein the first evaluation / annotation template in the first medical training module Is associated with a first medical training scenario and a first event module in the first medical training module and records a first plurality of events of the plurality of events and a second evaluation / annotation in a second medical training module Wherein the template is associated with a second medical training scenario and a second event module in the second medical training module and records a second plurality of events of the plurality of events,
/ RTI >
Wherein the first medical training scenario is different from the second medical training scenario and wherein at least some of the events of the first plurality of events correspond to at least some of the events of the second plurality of events, To test the technology,
Medical training systems (5).
The method according to claim 1,
Further comprising an instructor control device (25) connectable to the medical simulation management module (10) and adapted to use at least two of the evaluation / annotation templates (123) for input of student data.
Medical training systems (5).
The method according to claim 1,
Further comprising a student record database (50) connectable to the medical simulation management module (10)
Medical training systems (5).
A method for training and evaluation of a student to test a plurality of medical techniques,
Selecting (300) a plurality of medical training modules (15);
Executing (310) the plurality of medical training modules (15) on a mannequin, wherein each of the plurality of medical training modules
At least one medical training scenario for the training of the student in the plurality of medical technologies; And
At least one event module comprising a series of instructions for implementing at least one event to test one or more of the plurality of medical techniques
;
To access at least two evaluation / annotation templates (123) for recording results from one or more of the plurality of events testing one or more of the plurality of medical technologies used for different ones of the plurality of medical training modules (15) Generating (320) performance evaluation parameters (17) for performance steps of different ones of the plurality of medical training modules (15) by generating a scoring module for scoring of student performance on medical procedures;
Annotating a first evaluation / annotation template in a first medical training module to a first medical training scenario and a first event module in the first medical training module, wherein the first evaluation / Recording a first plurality of events;
Annotating a second evaluation / annotation template in a second medical training module to a second medical training scenario and a second event module in the second medical training module, wherein the second evaluation / Recording a second plurality of events;
(330) scoring the performance evaluation parameter (17) using the generated scoring module;
Storing (340) the performance evaluation parameter (17) scored in the storage device; And
Correlating at least some of the events of the first plurality of events to at least some of the events of the second plurality of events and testing the same medical technology among the plurality of medical techniques, Different steps from medical training scenarios
Methods for training and evaluation of students.
5. The method of claim 4,
The step of storing (340) the evaluation parameter (17) is performed in at least one of the student record database (50) or the instructor device (150)
Methods for training and evaluation of students.
The method according to claim 4 or 5,
Further comprising a debriefing step (350) of the student,
Methods for training and evaluation of students.
Logic means (300) for selecting a plurality of medical training modules (15);
Logic means (310) for executing said plurality of medical training modules (15) on a manikin;
Accessing at least two evaluation / annotation templates (123) for recording results from the plurality of events used for different ones of the plurality of medical training modules (15) and testing one or more of the plurality of medical techniques, Logic means (320) for generating performance evaluation parameters (17) relating to performance steps of different ones of said plurality of medical training modules (15) by generating a scoring module for scoring of student performance on said plurality of medical training modules (15);
Logic means for associating a first evaluation / annotation template in a first medical training module with a first medical training scenario and a first event module;
Logical means for associating a second evaluation / annotation template in a second medical training module with a second medical training scenario and a second event module;
Logic means (330) for scoring the evaluation parameter (17) using the scoring module generated; Logic means (330) for storing said evaluation parameter (17) scored in the storage device; And
Wherein the first medical training scenario is different from the second medical training scenario and wherein at least some of the events of the first plurality of events correspond to at least some of the events of the second plurality of events, Logic means for testing the technology,
Each of the plurality of medical training modules comprising at least one medical training scenario for the training of a student in the plurality of medical technologies,
Wherein at least one event module comprises a series of instructions for implementing at least one event to test one or more of the plurality of medical techniques,
Wherein the first evaluation / annotation template records a first plurality of events of the plurality of events,
Wherein the second evaluation / annotation template records a second plurality of events among the plurality of events,
A computer readable storage medium storing a computer program. delete delete

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